Uncertainty in ellipse fitting using a flatbed scanner: development and experimental verification

In the field of dimensional metrology, the use of optical measuring machines requires the handling of a large number of measurement points, or scanning points, taken from the image of the measurand. The presence of correlation between these measurement points has a significant influence on the uncertainty of the result. The aim of this work is the development of an estimation procedure for the uncertainty of measurement in a geometrically elliptical shape, taking into account the correlation between the scanning points. These points are obtained from an image produced using a commercial flat bed scanner. The characteristic parameters of the ellipse (coordinates of the center, semi-axes and the angle of the semi-major axis with regard to the horizontal) are determined using a least squares fit and orthogonal distance regression. The uncertainty is estimated using the information from the auto-correlation function of the residuals and is propagated through the fitting algorithm according to the rules described in Evaluation of Measurement Data—Supplement 2 to the ‘Guide to the Expression of Uncertainty in Measurement’—Extension to any number of output quantities. By introducing the concept of cut-off length, it can be observed how it is possible to take into account the presence of the correlation in the estimation of uncertainty in a very simple way while avoiding underestimation.

Uncertainty Estimation for Performance Evaluation of a Confocal Microscope as Metrology Equipment

Both in industry and research, the quality control of micrometric manufactured parts is based on the measurement of parameters whose traceability is sometimes difficult to guarantee. In some of these parts, the confocal microscopy shows great aptitudes to characterize a measurand qualitatively and quantitatively. The confocal microscopy allows the acquisition of 2D and 3D images that are easily manipulated. Nowadays, this equipment is manufactured by many different brands, each of them claiming a resolution probably not in accord to their real performance. The Laser Center (Technical University of Madrid) has a confocal microscope to verify the dimensions of the micro mechanizing in their own research projects. The present study pretends to confirm that the magnitudes obtained are true and reliable. To achieve this, a methodology for confocal microscope calibration is proposed, as well as an experimental phase for dimensionally valuing the equipment by 4 different standard positions, with its seven magnifications and the six objective lenses that the equipment currently has, in the x–y and z axis. From the results the uncertainty will be estimated along with an effect analysis of the different magnifications in each of the objective lenses.

Uncertainty in optical bio-sensors due to the spectral displacement of the interference modes of the transduction signal. Incertidumbre en bio-sensores ópticos asociada al desplazamiento espectral de los modos de interferencia de la señal de transducción

The analysis of the interference modes has an increasing application, especially in the field of optical biosensors. In this type of sensors, the displacement Δν of the interference modes of the transduction signal is observed when a particular biological agent is placed over the biosensor. In order to measure this displacement, the position of a maximum (or a minimum) of the signal must be detected before and after placing the agent over the sensor. A parameter of great importance for this kind of sensors is the period Pν of the signal, which is inversely proportional to the optical thickness h0 of the sensor in the absence of the biological agent. The increase of this period improves the sensitivity of the sensor but it worsens the detection of the maximum. In this paper, authors analyze the propagation of uncertainties in these sensors when using least squares techniques for the detection of the maxima (or minima) of the signal. Techniques described in supplement 2 of the ISO-GUM Guide are used. The result of the analysis allows a metrological educated answer to the question of which is the optimal period Pν of the signal. El análisis del comportamiento de los modos de interferencia tiene una aplicación cada vez más amplia, especialmente en el campo de los biosensores ópticos. En este tipo de sensores se observa el desplazamiento Δν de los modos de interferencia de la señal de transducción al reconocer un de-terminado agente biológico. Para medir ese desplazamiento se debe detectar la posición de un máximo o mínimo de la señal antes y después de dicho desplazamiento. En este tipo de biosensores un parámetro de gran importancia es el periodo Pν de la señal el cual es inversamente proporcional al espesor óptico h0 del sensor en ausencia de agente biológico. El aumento de dicho periodo mejora la sensibilidad del sensor pero parece dificultar la detección del mínimo o máximo. Por tanto, su efecto sobre la incertidumbre del resultado de la medida presenta dos efectos contrapuestos: la mejora de la sensibilidad frente a la dificultad creciente en la detección del mínimo ó máximo. En este trabajo, los autores analizan la propagación de incertidumbres en estos sensores utilizando herramientas de ajuste por MM.CC. para la detección de los mínimos o máximos de la señal y técnicas de propagación de incertidumbres descritas en el suplemento 2 de la Guía ISO-GUM. El resultado del análisis permite dar una respuesta, justificada desde el punto de vista metrológico, de en que condiciones es conveniente o no aumentar el periodo Pν de la señal.

Methodology of quantifying curvature of Fresnel lenses and its effect on CPV module performance

Fresnel lenses used as primary optics in concentrating photovoltaic modules may show warping produced by lens manufacturing or module assembly (e.g., stress during molding or weight load) or due to stress during operation (e.g., mismatch of thermal expansion between different materials). To quantify this problem, a simple method called “checkerboard method” is presented. The proposed method identifies shape errors on the front surface of primary lenses by analyzing the Fresnel reflections. This paper also deals with the quantification of the effects these curvatures have on their optical performance and on the electrical performance of concentrating modules incorporating them. This method can be used to perform quality control of Fresnel lenses in scenarios of high volume production.

1D and 2D neutral particle patterning by dielectrophoretic forces on z-cut Fe:LiNbO3 crystals

1D and 2D patterning of uncharged micro- and nanoparticles via dielectrophoretic forces on photovoltaic z-cut Fe:LiNbO3 have been investigated for the first time. The technique has been successfully applied with dielectric micro-particles of CaCO3 (diameter d = 1-3 μm) and metal nanoparticles of Al (d = 70 nm). At difference with previous experiments in x- and y-cut, the obtained patterns locally reproduce the light distribution with high fidelity. A simple model is provided to analyse the trapping process. The results show the remarkably good capabilities of this geometry for high quality 2D light-induced dielectrophoretic patterning overcoming the important limitations presented by previous configurations.

Análisis interferométrico de la influencia de un campo magnético axial sobre una estructura cilíndrica de cristal líquido

En el estudio de la propagación transversal de una radiación luminosa a través de un capilar con cristal líquido nemático, y cuyas moléculas se encuentran orientadas homeotrópicamente con respecto a las paredes internas de dicho capilar es necesario conocer de forma exacta la distribución espacial del director de cada una de las moléculas contenidas en el mismo. Esta distribución ha sido obtenida de forma empírica por Scudieri interpretando los resultados mediante la suposición de "lente delgada". Experimentalmente, mediante técnicas interferométricas, se obtienen dos grupos de franjas correspondiendo uno al índice de refraccción ordinario y siendo el otro función del ordinario y del extraordinario. El análisis de estas franjas es de una gran importancia a la hora de aplicar estructuras como la presente en Optica Integrada, ya que de ellas se puede inferir cuál es la respuesta de las moléculas de cristal líquido frente a campos externos, conocidos los valores del índice de refracción.

Estudio acústico de la sala 8 de los cines Kinépolis de Ciudad de la Imagen

Este proyecto consistira en la realization de un estudio aciistico sobre la sala 8 de los cines Kinepolis de Ciudad de la Imagen, que dispone de 408 butacas. Los cines Kinepolis es uno de los mayores complejos multisala de Europa. Cuenta con mas de 9.200 butacas en total distribuidas en 25 salas a las que se accede mediante dos grandes pasillos conectados por el hall. En 1998, ano de su apertura, el complejo recibio el Record Guinness a la sala cinematografica mas grande del mundo, que dispone de 996 butacas. El objetivo de este proyecto es conseguir caracterizar acusticamente una sala de cine a traves de la medicion de parametros acusticos de la sala y de un modelo virtual de la misma. Para llevar a cabo el proyecto, primero se van a realizar tanto una medicion geometrica como acustica de la sala mediante el sistema de medida DIRAC. Los resultados de estas mediciones nos serviran para construir y validar un modelo virtual de la sala real con el software de simulacion EASE. La medicion acustica se va a realizar con el sistema de medicion DIRAC. Este sistema nos dara information sobre una amplia variedad de parametros acusticos. En este proyecto no se va a trabajar con todos ellos, solo con los mas significativos. Estos se describen a continuacion en la introduccion teorica. La medicion geometrica nos va a servir para construir un modelo virtual que tenga las mismas dimensiones que la sala original. Esta medicion la realizaremos mediante un medidor laser y una cinta metrica. Una vez construido el modelo virtual, se procedera a su validacion. Este proceso se realiza ajustando el tiempo de reverberacion del modelo mediante la introduccion de distintos materiales acusticos en las superficies del mismo, de manera que, variando la absorcion de la sala, el tiempo de reverberacion promedio del modelo se asemeje lo mas posible al medido en la sala real. Este proceso tiene como objetivo comprobar que el modelo virtual tiene un comportamiento acustico similar al de la sala real. Es necesario validar adecuadamente el modelo para que las comparaciones y conclusiones sean fiables. Por ultimo, tras la simulacion acustica del modelo, se compararan los resultados simulados con los medidos en la sala. En este proceso se contrastaran algunos de los parametros que guardan relation con el tiempo de reverberacion. De esta manera se verificara si el tiempo de reverberacion es o no un parametro acustico fiable para la validacion de un modelo virtual de una sala de cine. Anteriormente se han realizado proyectos iguales de otras salas de diferente tamano de Kinepolis. El objetivo de realizar el mismo estudio en distintas salas, es comprobar si el tamano de la sala influye en la validacion de los modelos virtuales mediante el tiempo de reverberacion. ABSTRACT. This Project consists on the development of an acoustic research of the movie theater 8 of the Kinepolis complex in Ciudad de la Imagen, Madrid. This room has 408 spots. Kinepolis is one of the biggest multiplex complexes in Europe. It has 9,200 locations disposed in 25 rooms. There are two large corridors which give access to all of theaters. In the middle of the structure, there is the main hall that connects these corridors. In 1998, at the time when the complex was open, it was awarded with the Record Guinness for the biggest theater in the world, which has 996 locations. The target of this project is to successfully characterize the acoustics of a movie theater through reverberation time and a virtual model. In order to reach this goal, in the first place, we are going to perform both, an acoustic and a geometric measurement of the room using DIRAC measurement system. The results of these measures will allow us to build and validate a virtual model of the room, using the simulation software EASE. We are going to use the DIRAC system in order to accomplish the acoustic measure. This operation gives us a huge variety of acoustic parameters. Not all of these are going to be used for this research, only the most significant ones. These are described in the theoretical introduction. The geometric measure is essential to help us to build the virtual model, because the model has to be exactly equal as the real room. This measurement will be performed with an electronic distance meter and a measuring tape. Once the virtual model is finished, it will be proved. This validation process will be realized by adjusting the reverberation time in the model. We will change the walls materials, therefore, the overall absorption of the room will change. We want the model reverberation time resemble to the real one. This practice is going to ensure that the model acoustic performance is close to the real one. In addition, it has to be successfully validate of we want the future comparisons to be reliable. Finally, after the model virtual simulation, we will compare the simulated results with the measure in the room. In this process, we will compare not only the reverberation time, but others parameters that keep relation with the reverberation time. We will verify this way, if the reverberation time is or is not an appropriate acoustic parameter to validate a virtual model of a movie theater. There have been done others similar acoustic researches in different theaters with different sizes. The aim of performing similar researches in different rooms is to determine if the size of the room infers in the validation process.

Procesado Cuántico de la Información : Apuntes

Estos apuntes de Procesado Cuántico de la Información, escritos por Francisco José Rodríguez Fortuño, están basados en las clases y el material aportado por el Prof. Miguel Angel Muriel Fernández.

Analytical method to measure bending deformations in prismatic optical films

The aim of this work is to provide an analytical method based on experimental measurements in order to obtain the prismatic film deformation for different curvatures of Hollow Cylindrical Prismatic Light Guides (CPLG). To conform cylindrical guides is necessary bend the film to guide the light, changes induced by curving the film give rise to deformation shifts. Light losses affected by deformation has been experimentally evaluated and numerically analyzed. The effect of deformation in prism angle is specially increased for CPLG of curvatures higher than 20 m-1. An experimental method for accurate transmittance measurements related to bending is presented.

Improved and customized secondary optics for photo-voltaic concentrators

In this contribution the line flow method is applied to an optimized secondary optics in a photovoltaic concentration system where the primary optics is already defined and characterized. This method is a particular application of photic field theory. This method uses the parameterization of a given primary optics, including actual tolerances of the manufacturing process. The design of the secondary optics is constrained by the selection of primary optics and maximizes the concentration at a previously specified collection area. The geometry of the secondary element is calculated by using a virtual source, which sends light in a first concentration step. This allows us to calculate the line flow for this specific case. This concept allows designing more compact and efficient secondary optics of photovoltaic systems.

Robust fitting of Zernike polynomials to noisy point clouds defined over connected domains of arbitrary shape

A new method for fitting a series of Zernike polynomials to point clouds defined over connected domains of arbitrary shape defined within the unit circle is presented in this work. The method is based on the application of machine learning fitting techniques by constructing an extended training set in order to ensure the smooth variation of local curvature over the whole domain. Therefore this technique is best suited for fitting points corresponding to ophthalmic lenses surfaces, particularly progressive power ones, in non-regular domains. We have tested our method by fitting numerical and real surfaces reaching an accuracy of 1 micron in elevation and 0.1 D in local curvature in agreement with the customary tolerances in the ophthalmic manufacturing industry.

Method for the characterization of Fresnel lens flux transfer performance

Fresnel lenses and other faceted or micro-optic devices are increasingly used in multiple applications like solar light concentrators and illumination devices, just to name some representative. However, it seems to be a certain lack of adequate techniques for the assessment of the performance of final fabricated devices. As applications are more exigent this characterization is a must. We provide a technique to characterize the performance of Fresnel lenses, as light collection devices. The basis for the method is a configuration where a camera images the Fresnel lens aperture. The entrance pupil of the camera is situated at the focal spot or the conjugate of a simulated solar source. In this manner, detailed maps of the performance of different Fresnel lenses are obtained for different acceptance angles.

Application of principal component analysis in phase-shifting photoelasticity

Principal component analysis phase shifting (PCA) is a useful tool for fringe pattern demodulation in phase shifting interferometry. The PCA has no restrictions on background intensity or fringe modulation, and it is a self-calibrating phase sampling algorithm (PSA). Moreover, the technique is well suited for analyzing arbitrary sets of phase-shifted interferograms due to its low computational cost. In this work, we have adapted the standard phase shifting algorithm based on the PCA to the particular case of photoelastic fringe patterns. Compared with conventional PSAs used in photoelasticity, the PCA method does not need calibrated phase steps and, given that it can deal with an arbitrary number of images, it presents good noise rejection properties, even for complicated cases such as low order isochromatic photoelastic patterns. © 2016 Optical Society of America.

Resonant elements contactless coupled to bolometric micro-stripes

One of the main technical difficulties in the fabrication of optical antennas working as light detectors is the proper design and manufacture of auxiliary elements as load lines and signal extraction structures. These elements need to be quite small to reach the location of the antennas and should have a minimal effect on the response of the device. Unfortunately this is not an easy task and signal extraction lines resonate along with the antenna producing a complex signal that usually masks the one given by the antenna. In order to decouple the resonance from the transduction we present in this contribution a parametric analysis of the response of a bolometric stripe that is surrounded by resonant dipoles with different geometries and orientations. We have checked that these elements should provide a signal proportional to the polarization state of the incoming light.

Analysis of the spectral response of fractal antennas related with its geometry and current paths

Fractal antennas have been proposed to improve the bandwidth of resonant structures and optical antennas. Their multiband characteristics are of interest in radiofrequency and microwave technologies. In this contribution we link the geometry of the current paths built-in the fractal antenna with the spectral response. We have seen that the actual currents owing through the structure are not limited to the portion of the fractal that should be geometrically linked with the signal. This fact strongly depends on the design of the fractal and how the different scales are arranged within the antenna. Some ideas involving materials that could actively respond to the incoming radiation could be of help to spectrally select the response of the multiband design.